Vacuum heat insulator, hot insulating device using vacuum heat insulator, and electric water heater

ABSTRACT

In this vacuum heat insulator, an excellent heat insulating performance is obtained even at high temperature, and this excellent heat insulating performance is maintained for a long period. The hot insulating device and electric water heater using this vacuum heat insulator exhibit an excellent hot insulating performance, and are decreased in the power consumption for hot insulation. The vacuum heat insulator includes a laminate bag, and an insulating core placed in the laminate bag, and the inside of the laminate bag is evacuated in a vacuum state. The laminate bag is made of a laminate film. The laminate film includes a support layer, a deposition layer evaporated on the surface of the support layer, a protective layer placed at the surface side of the deposition layer, and a seal layer placed at the back side of the deposition layer. The deposition layer is formed of at least one material of metal and metal oxide. In this laminate film, (i) the support layer has a plastic film having a glass transition point of 87° C. or higher, (ii) the protective layer has a plastic film having a glass transition point of 87° C. or higher, (iii) the deposition layer has a property of transmitting high frequency magnetic field or (iv) the laminate bag has a seal portion formed by junction of the seal layer, and the laminate film further as a metal f oil placed at a position excluding the seal portion.

RELATED APPLICATIONS

This application is a divisional of Application 09/608,169, filed Jun.30, 2000, which claims priority of Japanese Application No. 11-185426,filed Jun. 30, 1999, Japanese Application No. 11-205899, filed Jul. 21,1999, and Japanese Application No. 11-326340, filed Nov. 17, 1999, thecontents of which are hereby incorporated by reference.

1. Field of the Invention

The present invention relates to a vacuum heat insulator used asinsulator, also referred to as a vacuum insulator, for jar-pot, alsoreferred to as electric thermo-pot, electric water heater, rice cooker,refrigerator, hot insulating device, heating device, cold insulatingdevice, induction heater, heating cooker, heating-hot insulating device,etc.

2. Background of the Invention

Conventional heat insulators include glass fiber, glass wool, foamedurethane, foamed styrene, and other plastic foams. Glass fiber has heatconductivity of about 0.035 kcal/mh° C. at 25° C. As better heatinsulators than such fiber and foams, vacuum heat insulators areproposed. Glass fiber and foamed styrene generally have heatconductivity of about five times or higher as compared with vacuum heatinsulator.

A conventional vacuum heat insulator comprises a laminate film baghaving gas barrier performance, and an insulating core contained in thislaminate bag, and the laminate bag is evacuated in a vacuum state. Thelaminate film bag with gas barrier performance has a laminated body ofplastic film and gas barrier layer. As the gas barrier layer, analuminum foil of about 6 to 10 μm in thickness, or aluminum depositionlayer placed on the surface of a plastic film is used. As the plasticfilm, polyethylene terephthalate or polypropylene is used. As theinsulating core, fine powder of silica, urethane foam or the like isused. The gas barrier layer in the vacuum heat insulator has a functionof preventing fresh air from invading into the laminate film bag bypenetrating through the laminate film bag.

Such conventional vacuum heat insulator is used in heat insulator of lowtemperature atmosphere in refrigerator or cold box.

An example of laminate film used in a conventional vacuum heat insulatoris shown in FIG. 6. In FIG. 6, a laminate film 5 has a protective layer1, gas barrier layer, and a heat fusion layer 4. The gas barrier layerincludes a base material 3, and a deposition layer 2 evaporated on thesurface of the base material 3. A protective layer, also referred to asa vacuum evaporated layer, 1 is formed as the outermost layer. The heatfusion layer 4 functions to seal the laminate film in a bag form by heatfusion. As the protective layer 1, a plastic film of 15 μm thickpolyamide-6 (tradename 6-Nylon) is used. The glass transition point of6-Nylon is 50° C. As the heat fusion layer 4, a plastic film ofpolypropylene of 50 μm in thickness is used. As the deposition layer 2,aluminum is used. The deposition film thickness of the deposition layeris about 50 nm. As the support layer 3, polyethylene terephthalate (PET)or polypropylene of about 25 μm in thickness is used.

The conventional vacuum heat insulator having such deposition layercannot be used at high temperature.

For example, if the vacuum heat insulator is used at high temperatureexceeding 90° C., the plastic film supporting the deposition layerexpands or shrinks thermally, and the deposition layer is cracked due todifference in coefficient of expansion between the plastic film anddeposition material. Through this crack, the air invades into the vacuumheat insulator, and the internal pressure of the vacuum heat insulatorrises. As a result, the insulating performance of the vacuum heatinsulator drops. Thus, in the conventional vacuum heat insulator, whenthermal stress is applied, the insulating performance of the vacuum heatinsulator deteriorates.

As the gas molecule becomes higher in temperature, its kinetic energyincreases in geometric series. Accordingly, at high temperature near100° C., the thin deposition layer deteriorates due to this kineticenergy, and lowers in function of suppressing penetration of gas. As aresult, the vacuum inside the vacuum heat insulator cannot bemaintained, and the insulating performance of the vacuum heat insulatordeclines.

In the vacuum heat insulator using deposition layer such as aluminumdeposition as gas barrier layer, as the protective layer adhered to thedeposition base material or deposition surface side, polyethyleneterephthalate (PET) is used. This PET film is poor in thermaldimensional stability, and since the deposition layer is very thin, thedeposition layer is broken by thermal shrinkage or contraction of thePET. As a result, the gas barrier performance of the vacuum heatinsulator is lowered, and the vacuum cannot be maintained in the vacuumheat insulator, thereby worsening the insulating performance.

On the other hand, in the conventional vacuum heat insulator having analuminum foil, heat conduction propagating through the aluminum foil isgreat. Accordingly, the heat quantity conducting in the creepingdirection of the vacuum heat insulator is greater than the heat quantityconducting in the sectional direction of the vacuum heat insulator.Therefore, in the composition of the aluminum foil formed on one side ofthe vacuum heat insulator contacting mutually with the aluminum foilformed on other side, or in the composition shorter in the mutualdistance, the heat conducts from one side to the aluminum foil, and doesnot conduct to other side. That is, the heat does not conduct throughthe insulating core filling up the inside of the laminate film bag. As aresult, the vacuum heat insulator may not exhibit sufficient insulatingperformance.

The conventional vacuum heat insulator having the aluminum foil cannotbe used as the heat insulator for induction heating cooker, inductionheating type rice cooker, or other induction heating device. That is,the aluminum foil itself is heated by induction heating, and the vacuumheat insulator having the aluminum foil does not function as heatinsulator.

As a conventional hot insulating device, a thermos bottle is known. Aconventional thermos bottle has double glass or stainless steelstructure, with the intermediate space evacuated to vacuum. That is, theconventional thermos bottle is a vacuum double container. Hot water orcold water is put in this vacuum double container, and is kept warm orcool. A warming cooker is proposed by installing an inner container forheating in an outer container having a vacuum double structure. The foodis put in the inner container, and the food is cooked by cooking rangeor the like, and when the food is heated to specified temperature, theinner container containing the food is transferred into the outercontainer, and is used in insulated state.

However, the vacuum double container requires a rigid containerwithstanding vacuum at atmospheric pressure. Accordingly, the thermosbottle having the vacuum double container is very heavy, and it isinconvenient when used as portable tool such as water bottle. Or, athermos bottle using vacuum double container of stainless steel materialcannot be heated from outside of the vacuum double container. Water isheated by other means, and the heated water is transferred into thevacuum double container. It is troublesome. The glass vacuum doublecontainer can transmit magnetic field for induction heating, andinduction heating is applicable, but the glass is very fragile andeasily broken. Other insulators such as glass fiber and plastic foamedmaterial is lower in the insulating performance than the vacuum doublecontainer, and the temperature of the contained hot water drops easily.

A conventional electric water heater consists of container and heater.The electric water heat with insulating function includes a container, aheater, and an insulator placed around the container. Water is put inthe container, and the heat is connected to the power source, and thewater boils. The electric water heater having an insulating function hasa function of keeping the hot water nearly at a specific temperature fora long time. The insulator used in the electric water heater having theinsulating function includes glass wool, other inorganic insulator, orreflective type insulator making use of a metal reflector.

However, the glass wool and similar insulators are excellent in thermaldurability, but are low in insulating performance. Accordingly, theconventional electric water heater using glass wool or similar insulatorrequires a large electric power for heat insulating purpose.

SUMMARY OF THE INVENTION

A vacuum heat insulator of the invention comprises a laminate bag, andan insulating core placed in the laminate bag. The inside of thelaminate bag is evacuated in a vacuum state. The laminate bag is made ofa laminate film. The laminate film includes a support layer, adeposition layer evaporated on the surface of the support layer, aprotective layer placed at the surface side of the deposition layer, anda seal layer placed at the back side of the deposition layer, and thedeposition layer is formed of at least one material of metal and metaloxide.

The laminate film has at least one feature selected from the groupconsisting of:

(i) the support layer has a plastic film having a glass transition pointof 87° C. or higher,

(ii) the protective layer has a plastic film having a glass transitionpoint of 87° C. or higher,

(iii) the deposition layer has a property of transmitting high frequencymagnetic field, and

(iv) the laminate bag has a seal portion formed by junction of the seallayer, and the laminate film further as a metal foil placed at aposition excluding the seal portion.

In this constitution, an excellent heat insulating performance isobtained even at high temperature, and this excellent heat insulatingperformance is maintained for a long period. Further, by turning on andoff the high temperature device using the vacuum heat insulator, ifthermal stress is applied to the vacuum heat insulator, the insulatingperformance of the vacuum heat insulator does not deteriorate, and anexcellent insulating performance is maintained.

The hot insulating device of the invention comprises a container foraccommodating the filling object, and the vacuum heat insulator disposedoutside of the container. In this constitution, a hot insulating devicehaving an excellent insulating performance is obtained.

The electric water heater of the invention comprises a container forholding liquid, a heater for heating the liquid, and the vacuum heatinsulator disposed outside of the container. In this constitution, thepower consumption for insulation is saved substantially.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a sectional view showing a structure of a vacuum heatinsulator in a first embodiment of the invention.

FIG. 1B is a sectional view showing a structure of a vacuum heatinsulator in other embodiment of the invention.

FIG. 2A is a sectional view showing a structure of a vacuum heatinsulator in a second embodiment of the invention.

FIG. 2B is a plan of a laminate film for explaining the shape ofaluminum foil used in the vacuum heat insulator in FIG. 2A.

FIG. 2C is a sectional view showing a structure of a vacuum heatinsulator in other embodiment of the invention.

FIG. 2D is a sectional view explaining a structure of aluminumdeposition layer.

FIG. 2E is a sectional view showing a structure of a vacuum heatinsulator in other embodiment.

FIG. 2F is a sectional view showing a detailed structure of aluminumfoil of the vacuum heat insulator shown in FIG. 2E.

FIG. 2G is a sectional view showing a structure of a vacuum heatinsulator in other embodiment of the invention.

FIG. 3A is a sectional view showing a structure of a vacuum heatinsulator in a third embodiment of the invention.

FIG. 3B is a sectional view showing a structure of an induction heatingdevice using the vacuum heat insulator shown in FIG. 3A.

FIG. 4A is a longitudinal sectional view of a hot insulating device in afourth embodiment of the invention.

FIG. 4B is a sectional view of a vacuum heat insulator of the hotinsulating device shown in FIG. 4A.

FIG. 4C is a sectional view of a laminate film of the hot insulatingdevice shown in FIG. 4A.

FIG. 4D is a longitudinal sectional view of a hot insulating device inother embodiment of the invention.

FIG. 4E is a sectional view of a laminate film of the hot insulatingdevice shown in FIG. 4D.

FIG. 5A is a longitudinal sectional view of an electric water heater ina fifth embodiment of the invention.

FIG. 5B is a sectional view of a vacuum heat insulator used in theelectric water heater in the embodiment of the invention.

FIG. 5C is a plan of the vacuum heat insulator used in the electricwater heater in the embodiment of the invention.

FIG. 5D is a perspective view of the vacuum heat insulator used in theelectric water heater in the embodiment of the invention.

FIG. 5E is a plan of the vacuum heat insulator used in the electricwater heater in the embodiment of the invention.

FIG. 5F is a perspective view of the vacuum heat insulator used in theelectric water heater in the embodiment of the invention.

FIG. 6 is a sectional view showing a structure of a conventional vacuumheat insulator.

REFERENCE NUMERALS

-   101 Protective layer-   102 Deposition layer-   103 Support layer, base material layer-   104 Heat fusion layer-   105 Insulating core-   108 Laminate bag-   109 Laminate bag-   201 Core-   202 Laminate film-   203 Seal portion-   204 Seal layer, heat fusion layer-   205 Gas barrier layer-   205 a First gas barrier layer-   205 b Second gas barrier layer-   206 Aluminum foil-   207 Protective layer-   209 Adhesive layer-   211 Support layer-   211 a First support layer, PEN film-   211 b Second support layer, PEN film-   212 a Aluminum deposition layer-   212 b Aluminum deposition layer-   303 Laminate film-   304 Seal layer-   305 Gas barrier layer-   306 Protective layer-   308 Induction heating device-   310 Vacuum heat insulator-   401 Container-   402, 404 Vacuum heat insulator-   406 Laminate film-   409 Core-   410, 423 Protective layer-   41, 424, 425 Gas barrier layer-   413, 427 Protective layer-   502 Water storage container-   513 Heater-   520 Vacuum heat insulator-   522 Core-   525 Seal layer, heat fusion layer-   526 Core-   527 Gas barrier layer-   529 Aluminum foil

DETAILED DESCRIPTION OF THE INVENTION

Exemplary embodiments of the invention are described below.

Exemplary Embodiment 1

In a vacuum heat insulator in an embodiment of the invention, a plasticfilm having a glass transition point of 87° C. or higher is used as asupport layer for supporting a deposition layer evaporating metal ormetal oxide. The deposition layer and support layer form the gas barrierlayer. Or the deposition layer forms the gas barrier layer. In thiscomposition, even at high temperature, cracking of the deposition layeris prevented. As a result, change of degree of vacuum inside the vacuumheat insulator in high temperature atmosphere is prevented, and anexcellent insulating performance is maintained for a long period.

A vacuum heat insulator in other embodiment of the invention has alaminate film laminating a support layer supporting one side ofdeposition layer evaporating metal or metal oxide, and a protectivelayer protecting other side of the deposition layer. As the protectivelayer, a plastic film having a glass transition point of 87° C. orhigher is used. In this composition, even at high temperature, crackingof the deposition layer is prevented. As a result, a vacuum heatinsulator having an excellent insulating performance is obtained.

A vacuum heat insulator in other embodiment of the invention has alaminate film laminating a support layer supporting one side ofdeposition layer evaporating metal or metal oxide, and a protectivelayer protecting other side of the deposition layer. As the supportlayer, a plastic film having a glass transition point of 87° C. orhigher is used. In this composition, even at high temperature, crackingof the deposition layer is prevented. As a result, a vacuum heatinsulator having an excellent insulating performance is obtained.

A vacuum heat insulator in other embodiment of the invention has alaminate film laminating a first deposition layer evaporating metal ormetal oxide, and a second deposition layer evaporating metal or metaloxide. The surface of the first deposition layer and the surface of thesecond deposition layer are adhered to each other. This laminate filmforms a bag, which is filled with an insulating core, and its opening issealed. The inside of the bag is evacuated to vacuum. In thiscomposition, even at high temperature, cracking of the deposition layeris prevented. As a result, a vacuum heat insulator having an excellentinsulating performance is obtained.

Preferably, as the plastic film, polyphenylene sulfide is used. Thispolyphenylene sulfide has a high glass transition point. Hence, furtherexcellent effects are obtained.

Preferably, as the plastic film, polyethylene naphthalate,polycarbonate, or polyimide is used. These plastic films have a highglass transition point. Hence, extremely excellent effects are obtained.

Embodiment 1a

An embodiment of the invention is described below.

FIG. 1A is a sectional view showing a composition of the embodiment. Thevacuum heat insulator of the invention has a laminate bag 108, and aninsulating core 105 filling up this laminate bag 108. As the core 105,silica powder is used. The laminate bag 108 includes a support layer103, a deposition layer 102 evaporated on the upper surface of thesupport layer 103, a protective layer 101 protecting the upper surfaceof the deposition layer 2, and a heat fusion layer 104. The laminate bag108 is formed of a laminate film laminating these layers. The depositionlayer 102 is formed by evaporating metal or metal oxide.

As the protective layer 101, a plastic film of 6-Nylon of 15 μm inthickness is used. The glass transition point of 6-Nylon is 50° C. Asthe heat fusion layer 104, a plastic film of polypropylene of 50 μm inthickness is used. As the deposition layer 102, aluminum is used. Thedeposition film thickness of the deposition layer is about 50 nm. As thesupport layer 103, polyphenylene sulfide of 25 μm in thickness, orpolyethylene naphthalate of 25 μm in thickness is used. The glasstransition point of polyphenylene sulfide resin is 87° C., and the glasstransition point of polyethylene naphthalate is 121° C. The insulatingcore 105 is formed in a thickness of about 10 mm in completed state. Theinside of the laminate bag 108 is evaluated to a vacuum of about 20Torr(mmHg) or less, that is, an atmospheric pressure of about 20 Torr orless.

The operation of the embodiment is explained. The vacuum heat insulatorof the embodiment is used as a heat insulator for heating cooker orheating-hot insulating device. The vacuum heat insulator of theinvention has a vacuum layer of about 10 mm in thickness by the actingas the core of the insulating core 105. This vacuum heat insulator has athermal conductivity of about 0.006 kcal/mh° C. (about 0.007 W/m-K). Inthis composition, the molecules of air transmitting heat from the hightemperature side to the low temperature side is extremely small. As theinsulating core 105, silica powder is used. The silica powder has athermal conductivity of about 10 W/m-K at 25° C. and atmosphericpressure 760 Torr (mmHg). Therefore, the thermal conductivity atatmospheric pressure is smaller than that of glass fiber. Hence, if thedegree of vacuum drops in the laminate bag, the degree of decline ofinsulating performance is small. Therefore, the heat insulation ismaintained for a long period. As a result, the vacuum heat insulator canbe used for a long period.

In the conventional vacuum heat insulator using polyethyleneterephthalate or other plastic film, when the vacuum heat insulator isused at temperature of about 85° C., the support layer 103 supportingthe deposition layer 102 expands or shrinks thermally. As a result, dueto difference in coefficient of thermal expansion between the supportlayer 103 and deposition layer 102, cracks are formed in the depositionmaterial forming the deposition layer 102. In the embodiment, bycontrast, as the support layer 103 for supporting the deposition layer102, polyphenylene sulfide with glass transition point of 87° C., or thepolyethylene naphthalate with glass transition point of 121° C. is used.Accordingly, when used at high temperature of about 85° C., the degreeof thermal expansion or shrinkage of the support layer 103 is verysmall. Therefore, cracking of the deposition layer 102 is prevented. Asa result, the deposition material forming the deposition layer 102maintains the role of preventing change of degree of vacuum as thebarrier layer. Hence, the vacuum heat insulator of the embodiment canmaintain the excellent heat insulating performance for a long period asa heat insulator of the device having high temperature.

In the foregoing explanation, as the support layer 103, polyphenylenesulfide or polyethylene naphthalate is used, but other plastic resins aslisted in Table 1 may be also used TABLE 1 Plastic resin with glasstransition point of 87° C. or higher Plastic resin Glass transitionpoint(° C.) Polystyrene  87 Polyphenylene sulfide  87 Denaturedpolyphenylene ether 100˜220 Cellulose triacetate 107 Polyethylenenaphthalate 121 Polytetrafluoroethylene 127 Polyether ether ketone 143Polyallyl ether nitrile 145 Polycarbonate 150 Polysulfone 190Polyarylate 193 Polyether imide 217 Polyether sulfone 225 Polyimide250˜500 Polyamide imide 280˜290 Polybenzoimidazole 421

Embodiment 1b

Other embodiment of the invention is described. FIG. 1B is a sectionalview showing a structure of a vacuum heat insulator of the otherembodiment of the invention.

In FIG. 1B, the vacuum heat insulator of the invention comprises a firstsupport layer 103, a first deposition layer 102 evaporated to this firstsupport layer 103, a second support layer 103 a, and a second depositionlayer 102 a evaporated to this second support layer 103 a. The surfaceof the first deposition layer 102 and the surface of the seconddeposition layer 102 a are adhered to each other. By thus stackedlaminate film, a laminate bag 109 is formed. The first deposition layer102 is disposed by vapor deposition of metal or metal oxide. The seconddeposition layer 102 a is disposed by vapor deposition of same metal ormetal oxide as the first deposition layer 102. The second support layer103 has two functions, that is, function as the base material of thesecond deposition layer 102 a and function as protective layer. Thecomposition of the seal layer 104, support layer 103, and insulatingcore 105 is same as the composition explained in embodiment 1a.

In this embodiment, the laminate bag 109 has two deposition layers, thatis, first deposition layer 102 and second deposition layer 102 a.Accordingly, both first support layer 103 for supporting the firstdeposition layer 102 and second support layer 103 a for supporting thesecond deposition layer 102 a also have the function as protective layerfor protecting the two deposition layers 102, 102 a. Therefore, when thefirst support layer 103 and second support layer 103 a are made ofplastic film having glass transition point of 87° C. or higher,excellent effects equivalent to or superior to those of embodiment 1aare obtained. That is, generation of stress is more effectivelyprevented. Therefore, if the vacuum heat insulator of the embodiment isused at high temperature, cracking of the deposition layers 102, 102 ais prevented. As a result, the deposition material forming thedeposition layers 102, 102 a maintains the role of preventing change ofdegree of vacuum as barrier layer. Hence, the vacuum heat insulator ofthe embodiment can maintain an excellent heat insulating performance fora long period as the insulator for devices having high temperature.Moreover, since two support layers having deposition layers aredisposed, better effects than in embodiment la are obtained.

Embodiment 1c

An experiment was conducted to verify the effects of embodiment la andembodiment lb. Results of the experiment are explained.

Samples of vacuum heat insulator used in the experiment were prepared inthe following procedure.

Test sample 1 has the structure of embodiment 1a (structure in FIG. 1A).That is, three sides of the laminate film shown in FIG. 1A are heatedand fused with the seal layer 104 overlapped inside. Thus, a rectangularlaminate bag 108 of 200 mm in length and 300 mm in width is prepared.

This laminate bag 108 is filled with silica powder as insulating core105. In this state, the inside of the laminate bag 108 is evacuated toabout 0.5 Torr. Finally, the remaining opening of the laminate bag 108is heated and fused. As a result, test sample 1 of vacuum heat insulatorin 10 mm in thickness is obtained.

Test sample 2 has the structure of embodiment 1b (structure in FIG. 1B).That is, three sides of the laminate film shown in FIG. 1B are heatedand fused with the heat fusion layer 104 overlapped inside. Thus, arectangular laminate bag 109 of 200 mm in length and 300 mm in width isprepared.

This laminate bag 109 is filled with silica powder as insulating core105. In this state, the inside of the laminate bag 109 is evacuated toabout 0.5 Torr. Finally, the remaining opening of the laminate bag 109is heated and fused. As a result, test sample 2 of vacuum heat insulatorin 10 mm in thickness is obtained.

Test sample 3 has the structure of the prior art shown in FIG. 6. Thatis, the support layer 3 is polyethylene terephthalate (PET) of about 25μm in thickness. The protective layer 1 is 6-Nylon. Other composition oftest sample 3 is same as the composition of test sample 1.

Thus prepared test sample 1, test sample 2 and test sample 3 weremeasured in the following steps.

Measurement 1: Right after preparation, the internal pressure of thevacuum heat insulator was measured.

Measurement 2: After letting stand in the atmosphere of 85° C. for 3days, the internal pressure of the vacuum heat insulator was measured.

Measurement 3: After letting stand in the atmosphere of 85° C. for 10days, the internal pressure of the vacuum heat insulator was measured.

Measurement 4: After letting stand in the atmosphere of 100° C. for 3days, the internal pressure of the vacuum heat insulator was measured.

Measurement 5: After letting stand in the atmosphere of 100° C. for 10days, the internal pressure of the vacuum heat insulator was measured.

The internal pressure of the vacuum heat insulator was measured in thefollowing procedure. The test sample was put in a chamber, and thechamber was evacuated until the sample was deformed, and the pressure atthis time was measured. That is, the moment when the degree of vacuum inthe chamber exceeds the degree of vacuum of the test sample, the testsample is pulled outside due to difference in pressure between insideand outside of the vacuum heat insulator, and the vacuum heat insulatoris deformed. The pressure (the degree of vacuum in Torr) when the testsample was deformed was measured.

Results of measurement are summarized in Table 2. Table 2 teaches thefollowing.

(1) In samples B, D, E using polyethylene naphthalate resin of whichglass transition point is 121° C. as support layer 103 or protectivelayer 101, excellent gas barrier performance and degree of vacuum aremaintained even after high temperature durability test at both 85° C.and 100° C.

(2) In samples A, C using polyphenylene sulfide resin of which glasstransition point is 87° C. as support layer 103 or protective layer 101,excellent gas barrier performance and degree of vacuum are maintainedeven after high temperature durability test at 85° C.

(3) In sample E using polyphenylene sulfide resin of which glasstransition point is 87° C. as both support layer 103 and protectivelayer 101, excellent gas barrier performance and degree of vacuum aremaintained even after high temperature durability test at 100° C.

(4) In samples G, H having two deposition layers, and a plastic filmhaving glass transition point of 87° C. or higher disposed at both sidesof the deposition layers, further excellent gas barrier performance anddegree of vacuum are maintained. TABLE 2 Sample No. Sample Initial 85°C. 100° C. 1 A 1 2/2 9/20 or more B 1 1/1 2/2 C 1 1/2 10/20 or more D 11/2 2/2 E 1 1/1  5/13 F 1 1/1 1/2 2 G 1 1/1 2/4 H 1 1/1 1/2 3Comparative 1  4/15 20 or more/ example 20 or moreNote 1.SamplesA: Polyphenylene sulfide resin used as support layerB: Polyethylene naphthalate resin used as support layerC: Polyphenylene sulfide resin used as protective layerD: Polyethylene naphthalate resin used as protective layerE: Polyphenylene sulfide resin used as protective layerF: Polyethylene naphthalate resin used as support layer and protectivelayerG: Polyphenylene sulfide resin used two support layersH: Polyethylene naphthalate resin used as two support layersNote 2.Unit of degree of vacuum: TorrNote 3.Indication of measurement result at 85° C. and 100° C.

3 days/10 days

As explained above, by the constitution of the invention, if used athigh temperature, the degree of thermal expansion or thermal shrinkageof the support layer is very small. Hence, cracking of deposition layeris prevented. As a result, the deposition material forming thedeposition layer 2 maintains the role of preventing change of degree ofvacuum as barrier layer. As a result, the vacuum heat insulator of theinvention maintains an excellent insulating performance for a longperiod as the insulator for device having high temperature.

Exemplary Embodiment 2

A vacuum heat insulator in other exemplary embodiment of the inventioncomprises a laminate bag, an insulating core put in the laminate bag,and an aluminum foil. The aluminum foil is placed between the laminatefilm and insulating core, or disposed in the laminate film. The insideof the laminate bag is evacuated to vacuum. The insulating core isdisposed in the laminate bag in sealed state. The laminate bag is formedof a support layer having an aluminum deposition layer, and a laminatefilm having a seal layer. At least one side of the laminate bag has aheat seal portion. The aluminum foil is disposed in a region excludingthe heat seal portion. In this constitution, a vacuum heat insulatorhaving an excellent insulating performance at high temperature isobtained.

Preferably, the support layer has polyethylene naphthalate. In thiscomposition, a vacuum heat insulator capable of insulating for a longtime even in high temperature atmosphere is obtained.

Preferably, the laminate film has a first support layer, a firstaluminum deposition layer evaporated to the first support layer, asecond support layer, and a second aluminum deposition layer evaporatedto the second support layer, and the first aluminum deposition layer andsecond aluminum deposition layer are laminated in mutually facing state.

In this constitution, invasion of gas into the laminate bag isprevented, and the gas barrier performance is enhanced extremely.Further, a vacuum heat insulator capable of insulating for a long timeeven in high temperature atmosphere is obtained.

Preferably, the aluminum foil is adhered to the laminate film. Thisaluminum foil, after being adhered to the laminate film, is formed intoa specified shape by etching. In this constitution, the aluminum foil ofa fine shape can be disposed accurately. As a result, a vacuum heatinsulator of high performance is obtained.

Preferably, the aluminum foil is laminated on the laminate film. In thisconstitution, processing is easy, and a vacuum heat insulator of highperformance is obtained.

Preferably, the aluminum foil is disposed between the support layerhaving an aluminum deposition layer and the seal layer. In thisconstitution, a vacuum heat insulator having an excellent durability andexcellent insulating performance is obtained.

Preferably, the aluminum foil is disposed between the first aluminumdeposition layer and second aluminum deposition layer. In thisconstitution, a vacuum heat insulator having an excellent durability andexcellent insulating performance is obtained.

Preferably, the support layer having the aluminum deposition layer isdisposed between the aluminum foil and the seal layer. In thisconstitution, a vacuum heat insulator having an excellent durability andexcellent insulating performance is obtained.

Embodiment 2a

A specific embodiment of the invention is explained below. FIG. 2A is asectional view showing a structure of vacuum heat insulator of theembodiment. FIG. 2B is a plan showing a structure of the embodiment. Inthe vacuum heat insulator of the embodiment, a laminate bag is formed oftwo laminate films 202. An insulating core 201 is put in the laminatebag. That is, the insulating core 201 is covered with two laminate films202. The inside of the laminate bag is evacuated to vacuum, and a sealportion 203 is sealed. The material of the core 201 is inorganic mattersuch as silica powder, pearlite or glass wool, or organic matter such asmelamine or urethane. In this embodiment, power of synthetic silica isused. The laminate film 202 has a polyethylene naphthalate film (PENfilm) as protective layer 207, a polypropylene film as seal layer 204, aPEN film as support layer 211, and an aluminum deposition layer 212evaporated to this support layer 211. The support layer 211 and aluminumdeposition layer 212 form a gas barrier layer 205. Between this gasbarrier layer 205 and protective layer 207, an aluminum foil 206 islaminated. The thickness of the aluminum foil 206 is about 6 μm. Asshown in FIG. 2B, this aluminum foil 206 is disposed in a region of thelaminate film 202 excluding at least a part of the seal portion 203.That is, the aluminum foil 206 is disposed so as not to contact with theseal portion 203. As the seal layer 204, an undrawn polypropylene of 50μm in thickness is used. The thickness of the aluminum deposition layer215 is about 50 nm. As the protective layer 207, a PEN film of 12 μm inthickness is used.

The action of the embodiment is explained. When the vacuum heatinsulator of the embodiment is assembled in a heating-hot insulatingdevice such as jar-pot, a temperature difference occurs at both sides ofthis vacuum heat insulator. That is, one side of the vacuum heatinsulator is contacting with boiling water, and its temperature isnearly 100° C. The other side of the vacuum heat insulator is contactingwith the outer wall of the jar-pot, and its temperature is roomtemperature. In this state, the heat quantity of the boiling water istransmitted to the outside of the jar-pot through the vacuum heatinsulator. In this state, there is heat conduction in both sectionaldirection and creeping direction of the vacuum heat insulator. This heattransfer quantity is proportional to the product of the thermalconductivity and thickness of the vacuum heat insulator. In thecomposition of this embodiment, the product of the thermal conductivityand thickness is 0.01 [{W/(m·K)}·m] in the seal layer 204, 1.4[{W/(m·K)}·m] in the aluminum foil 206, 0.012 [{W/(m·K)}·m] in thealuminum deposition layer 205, and 0.003 [{W/(m·K)}·m] in the protectivelayer 207. That is, the aluminum foil 206 has the thermal conductivityof about 50 times of the total of the other parts.

As a result, when the vacuum heat insulator of the embodiment is used,the thermal conductivity in the creeping direction of the vacuum heatinsulator is extremely small. That is, since the aluminum foil 206 isnot present in the seal portion 203, the heat quantity of moving theseal portion 203 free from aluminum foil 206 is about 1/50 of thecentral part having the aluminum foil 206. Therefore, as mentionedabove, the heat conduction from the creeping direction of the vacuumheat insulator of the embodiment is very small. Moreover, since theinsulating core 201 evacuated to vacuum is present in the sectionaldirection of the vacuum heat insulator of the embodiment, the heatconduction in the sectional direction is extremely small. As a result, avacuum heat insulator having an extremely excellent insulatingperformance is obtained.

For example, by turning on and off the power source of the device usingthe vacuum heat insulator, the vacuum heat insulator is exposed totemperature stress all the time. The vacuum heat insulator of theembodiment also has an excellent resistance to such temperature stress.That is, as the support layer 211 for forming the aluminum depositionlayer 212, a PEN film is used. The PEN film 211 has a high melting pointand a high glass transition point, and also has an excellent dimensionalstability against temperature changes. Accordingly, when the vacuum heatinsulator is exposed to thermal stress, the difference is small betweenthe shape change due to expansion and shrinkage of the aluminumdeposition layer 212 and the shape change due to expansion and shrinkageof the PEN film itself. Hence, if exposed to thermal stress, stress onthe aluminum deposition layer 212 hardly occurs. That is, even in hightemperature atmosphere, formation of pin hole in the aluminum depositionlayer 212 is prevented. As a result, the laminate film 202 having thealuminum deposition layer 215 acts as a gas barrier layer of long lifeand high reliability.

Thus, according to the constitution of the embodiment, a vacuum heatinsulator having an excellent insulating performance even inhigh-temperature use is obtained.

Incidentally, when the laminate film 202 has a support layer ofpolyethylene naphthalate, the melting point and glass transition pointof the support layer are high, and the support layer has an excellentdimensional stability against temperature changes, and therefore if usedin high temperature atmosphere, formation of pin hole in the aluminumdeposition layer 212 is prevented, so that a vacuum heat insulatorhaving an excellent insulating performance even in high-temperature useis obtained.

The aluminum foil 206 is formed by etching. That is, after the aluminumfoil 206 is entirely adhered to the inside of the protective layer 207,a specified area of the aluminum foil is melted and removed by etchingas shown in FIG. 2B. An alkaline solution is used as the etchant. Sinceetching is a fine process, an aluminum foil of a desired shape can beformed accurately. Therefore, a vacuum heat insulator of highperformance is obtained.

Embodiment 2b

FIG. 2C is a sectional view showing a vacuum heat insulator in otherembodiment of the invention. In FIG. 2C, a laminate film 202 has a firstgas barrier layer 205 a and a second gas barrier layer 205 b. The firstgas barrier layer 205 a has a first PEN film 211 a, and a first aluminumdeposition layer 212 a evaporated to the first PEN film 211 a. Thesecond gas barrier layer 205 b has a second PEN film 211 b, and a secondaluminum deposition layer 212 b evaporated to the second PEN film 211 b.The first aluminum deposition layer 212 a and second aluminum depositionlayer 212 b are adhered in mutually facing state. The aluminum foil 206is laminated to the inside of the first PEN film 211 a.

A detailed sectional view of the laminate film used in the embodiment isgiven in FIG. 2D. In FIG. 2D, the laminate film has the first gasbarrier layer 205 a and the second gas barrier layer 205 b. The firstgas barrier layer 205 a has the first PEN film 221 a as the firstsupport layer 211 a and the first aluminum deposition layer 212 a. Thesecond gas barrier layer 205 has the second PEN film 211 b as the secondsupport layer and the second aluminum deposition layer 212 b. The firstaluminum deposition layer 212 a and second aluminum deposition layer 212b are mutually adhered with an adhesive 209. Each thickness of the firstaluminum deposition layer 212 a and second aluminum deposition layer 212b is about 50 nm. If the thickness of the aluminum deposition layer issmall, generally, pin holes 210 are likely to occur, and the gas maypass through the pin holes to change the internal atmospheric pressurein the vacuum heat insulator, thereby lowering the insulatingperformance of the vacuum heat insulator. However, when the firstdeposition layer 212 a and second deposition layer 212 b are adhered toconfront each other, the formed pin holes 210 are mutually plugged bythe first PEN film 211 a and second PEN film 211 b. It hence preventschange of internal atmospheric pressure due to invasion of gas into thevacuum heat insulator. As a result, an excellent insulating performanceis maintained for a long period.

At this time, as shown in FIG. 2C, the aluminum foil 206 is disposedbetween the first gas barrier layer 205 a and seal layer 204. Thethickness of the aluminum foil 206 is about 6 μm. Accordingly, when athermal stress is applied, the laminate film 202 shrinks, and rubsagainst the core 201 or external part, and at this time the first gasbarrier layer 205 a and second gas barrier layer 205 b act effectivelyto protect the vacuum heat insulator. Therefore, the vacuum heatinsulator of the invention has both excellent durability and excellentinsulating performance.

Embodiment 2c

FIG. 2E is a sectional view showing a structure of a further differentembodiment of the invention. FIG. 2F is a sectional view showing adetailed structure. In this embodiment, an aluminum foil 206 is disposedbetween a first gas barrier layer 205 a and a second gas barrier layer205 b, and they are adhered together tightly with an adhesive. Thealuminum foil 206 is disposed in a region excluding a part of a sealportion 203. As a support layer 211, a PEN film is used. As shown inFIG. 2F, at this time, the adhesive is applied in a range narrower thanthe aluminum foil 206. Therefore, an adhesive-free space 213 is likelyto be formed at the end of the aluminum foil 206. When such space 213 isformed, it is possible that air or gas may pass through the space 213 toinvade into the laminate film. By contrast, in the vacuum heat insulatorof the embodiment, since the aluminum foil 206 is disposed between thefirst gas barrier layer 205 a and second gas barrier layer 205 b, ifspace 213 is formed, invasion of air is blocked by the PEN films 211 a,211 b having the first aluminum deposition layer 212 a and secondaluminum deposition layer 212 b.

According to the embodiment, only by the processing of adhering thealuminum foil 206 to the PEN film, the laminate film can be manufacturedeasily. Therefore, processing is very easy. Further, a vacuum heatinsulator having an excellent insulating performance is obtained. Stillmore, not requiring chemical processing such as etching, there is norisk of deterioration of resin, and a vacuum heat insulator usable for along period is obtained.

Embodiment 2d

FIG. 2G is a sectional view showing a structure of other differentembodiment of the invention. In this embodiment, a first gas barrierlayer 205 a and a second gas barrier layer 205 b are disposed between analuminum foil 206 and a seal layer 204, and the outer surface of thealuminum foil 206 is covered with a protective layer 208. As theprotective layer 208, polyamide (tradename Nylon) is used.

Accordingly, if a space 213 as explained in embodiment 2 c is formed atthe end of the aluminum foil 206, since there are two layers, first gasbarrier layer 205 a and second gas barrier layer 205 b, invasion of gasthrough the space 213 is prevented. Therefore, according to theembodiment, a vacuum heat insulator having an excellent insulatingperformance usable for a long period is obtained.

As explained herein, the constitution of the embodiment presents avacuum heat insulator having an excellent durability and excellentinsulating performance usable for a long period even at hightemperature.

Exemplary Embodiment 3

A vacuum heat insulator in a different exemplary embodiment of theinvention comprises a laminate film bag and an insulating core disposedin the laminate bag. The inside of the laminate bag is evacuated tovacuum. The laminate bag is made of a laminate film. The laminate filmhas a gas barrier layer with gas barrier performance. The gas barrierlayer has a ductile metal. The metal has a thermal conductivity of 100W/m·K or less at 300K. In this constitution, a vacuum heat insulatorhaving an excellent insulating performance not deteriorating for a longperiod is obtained.

A vacuum heat insulator in a further different exemplary embodiment ofthe invention comprises a laminate film bag and an insulating coredisposed in the laminate bag. The inside of the laminate bag isevacuated to vacuum. The laminate bag is made of a laminate film. Thelaminate film has a gas barrier layer with gas barrier performance. Thegas barrier layer has a property of passing through a high frequencymagnetic field. In this constitution, by applying high frequencymagnetic field in the cooking container, the cooking container is heatedby induction, and an excellent insulating performance is obtained as theinsulator for insulating the induction heating device for heating wateror food.

Preferably, the metal has a metal foil. In this constitution, anexcellent insulating performance is obtained for insulation of inductionheating device.

Preferably, the metal foil is a stainless steel with a thickness of 50μm or less. The stainless steel allows to pass high frequency magneticfield, and hence heating or burning of metal foil is prevented.Therefore, when vacuum heat insulator is used as the insulator of theinduction heating cooker, lowering of induction heating efficiency ofthe induction heating device is prevented, and an excellent insulatingperformance is obtained at the same time. This vacuum heat insulator canbe used for insulation of induction heating device.

Preferably, the metal is SUS430, SUS304, SUS301, SUS316, or a pluralityof combinations thereof. This constitution realizes a vacuum heatinsulator having excellent heat resistance, excellent durability andexcellent insulating effect, and usable as insulator for insulation ofinduction heating device.

Preferably, the metal foil is a titanium foil with thickness of 50 μm orless. This constitution realizes a vacuum heat insulator havingexcellent heat resistance, excellent durability and excellent insulatingeffect, and usable as insulator for insulation of induction heatingdevice.

Preferably, the laminate film has a protective layer, and thisprotective layer has one layer of heat resistant organic film or aplurality of layers of heat resistant organic film. In thisconstitution, deterioration of laminate film at high temperature isprevented. As a result, if used at high temperature, a vacuum heatinsulator maintaining an excellent insulating performance for a longperiod is obtained.

Preferably, the heat resistant organic film has polyethyleneterephthalate, polyethylene naphthalate, polyimide, or polyphenylsulfide. In this constitution, deterioration of laminate film at hightemperature is prevented. As a result, if used at high temperature, avacuum heat insulator maintaining an excellent insulating performancefor a long period is obtained.

Embodiment 3a

A specific embodiment of the invention is described below. FIG. 3A showsa sectional view showing a structure of a vacuum heat insulator of theembodiment. The vacuum heat insulator of the embodiment comprises aninner bag 302, an insulating core 301 disposed in the inner bag 302, anda laminate film 303. The laminate film 303 is formed like a bag, and alaminate bag is formed. The insulating core 301 disposed in the innerbag 302 is placed in the laminate film 303 in bag form. The laminatefilm 303 has a heat fusion layer 304, a gas barrier layer 305, and aprotective layer 306. The laminate film 303 has an adhesion portion 307.The laminate bag is sealed in an enclosed state by heating and fusingthe adhesion portion 307. The inside of the laminate bag is evacuated toa vacuum state.

As the core 301, fine powder of silica or pearlite, or urethane foam orthe like may be used. In this embodiment, the core 301 is syntheticsilica powder of fine particle size. The synthetic silica powder havingfine particles has a small thermal conductivity. This synthetic silicapowder has a very small thermal conductivity, regardless of thepressure, at pressure of about 10 Torr or less. Accordingly, if used athigh temperature where motion of air molecules is large, the vacuum heatinsulator using synthetic silica powder exhibits an excellent heatinsulating performance.

As the heat fusion layer 304, polyethylene, high density polyethylene,polyacrylonitrile, polypropylene, or the like may be used. In thisembodiment, as the heat fusion layer 304, homopolymer of undrawnpolypropylene having a high crystallinity is used. The undrawnpolypropylene does not deteriorate if left over in the atmosphere ofhigh temperature of about 100° C. for a long period.

The gas barrier layer 305 has a role of holding the vacuum inside thevacuum heat insulator. The degree of vacuum inside the vacuum heatinsulator (that is, the internal pressure) is about 20 Torr or less.Generally, due to the mechanical external force such as thermal stress,the gas barrier effect of the gas barrier layer 305 is lowered, and thegas invades into the laminate bag, so that the internal pressure climbsup. As a result, the insulating performance of the vacuum heat insulatoris lowered.

In this embodiment, the gas barrier layer 305 is a metal havingductility and thermal conductivity of 100 W/m·K or less at 300K. Sincethe metal is ductile, if the thin metal foil is fabricated by theprocess of spreading the metal thinly, formation of pin holes isprevented. Besides, since the thermal conductivity of the metal issmall, heat conduction from the end of the laminate film having themetal can be prevented. As a result, the insulating performance of thevacuum heat insulator is enhanced.

The action of the embodiment is explained. The vacuum heat insulatorshown in FIG. 3A exhibits an excellent heat insulating performance whenused in the induction heater making use of induction heating of course,this vacuum heat insulator exhibits a superior insulating performancewhen used in refrigerator, cold box, or ordinary heating or hotinsulating device.

As induction heating device, cooking tool, jar rice cooker, hot-plate,hot-pan, and other heating device heated by induction heating areproposed. In the induction heating device, high frequency magnetic fieldof about, for example, 25 kilohertz is generated from the high frequencycoil, and this high frequency magnetic field is applied to the cookingcontainer of the cooking device, and the cooking container is heated byinduction. That is, by application of high frequency magnetic field, aneddy current is generated in the metal for composing the cookingcontainer. By this eddy current, Joule heat is generated. By thisinduction heating, the food contained in the cooking container iscooked.

In such apparatus having a structure of heating the cooking container bythe high frequency magnetic field, the vacuum heat insulator having themetal cannot exhibit its excellent insulating performance depending onthe type of the metal. For example, the high frequency magnetic fieldgenerated by the apparatus when cooking is applied to the metal forcomposing the gas barrier layer of the insulator, this metal itself maybe heated by induction heating. As a result, the gas barrier layer isbroken. Hence, the vacuum heat insulator is destroyed.

The embodiment presents a vacuum heat insulator capable of avoiding sucheffects of the high frequency magnetic field.

The induction heating phenomenon occurring due to crossing with the highfrequency magnetic field varies in its behavior depending on the typeand thickness of the metal to be heated. The stainless steel, titanium,iron, chromium and carbon steel having a relatively large electricresistance are excessively heated by induction heating at the thicknessin the micron order. When the thickness of these metals is in the micronorder, these metals are hardly heated. In particular, in the stainlesssteel or titanium having a large electric resistance, these metals arehardly heated when the thickness is about 20 μm or less. When thethickness of these metals is about 5 μm or less, these metals are notheated practically. The metal of thickness in the micron order also hasa property of passing the high frequency magnetic field generated fromthe high frequency coil. The metal having a small electric resistancesuch as aluminum and copper is not heated by induction heating in thethickness range of micron order. However, when the metal thickness is inthe order of about 7 μm, the metal is heavily heated. For example, invapor deposition technique, sputtering technique, and etching technique,aluminum in thickness of about 0.05 to about 1 μm passes high frequencymagnetic field and is not heated by induction.

That is, in this embodiment, as the gas barrier layer 305 shown in FIG.3A, a ductile metal having thermal conductivity of 100 W/m·K at 300K isused. By using a ductile metal, it is easy to manufacture a thinlyprocessed metal foil. It is therefore possible to process to the metalto a thickness not to be heated by induction when put in the magneticfield such as high frequency magnetic field. That is, a metal foilpreventing formation of pin hole is formed. Further, when using adeposition layer evaporating metal to the support layer, depositionlayer free from pin hole is formed. Thus, the gas barrier layer 305capable of maintaining an excellent gas barrier characteristic isobtained. Further, by using a metal having a small thermal conductivity,a vacuum heat insulator having an extremely excellent insulating effectis obtained. The thermal conductivity at average temperature of 300K is100 (W/m·K), and usable examples of ductile metal include iron (80W/m·K), nickel (90 W/m·K), platinum (71 W/m·K), tin (73 W/m·K), titanium(20W/m·K), stainless steel (15W/m·K), and carbon steel (50 W/m·K).

In this embodiment, since the gas barrier 305 is made of a very thinmaterial such as metal foil or deposition layer, the gas barrier layer305 is likely to be damaged. If the gas barrier layer 305 is damaged,the internal vacuum of the film bag cannot be maintained, and theinsulating performance of the vacuum heat insulator is lowered. In thisembodiment, accordingly, a protective layer 306 is placed outside of thegas barrier layer 305. The protective layer 306 of the embodiment ispolyethylene terephthalate (PET), polyethylene naphthalate (PEN),polyimide (PI), polyphenyl sulfide (PPS), or other heat resistant film.By using such heat resistant films, if the vacuum heat insulator is usedat high temperature of about 100° C., thermal deterioration ofprotective layer is prevented. As a result, a vacuum heat insulatorcapable of maintaining an excellent insulating performance is obtained.As the protective layer 306, when using polyamide resins such aspolyamide-6 (tradename Nylon 6) or polyamide 66 (tradename Nylon 66),these effects are slightly inferior because Nylon 6 and Nylon 66 tend todeteriorate thermally at high temperature.

Examples for verifying these effects of the embodiment are explainedbelow.

Embodiment 3b

Using the laminate film having the following gas barrier layer 305,various vacuum heat insulators are prepared.

Prior art 1: Aluminum foil of 7 μm in thickness.

Prior art 2: Aluminum deposition layer of 0.05 μm in thicknessevaporated on PET film.

SUS foil A of embodiment: Metal foil using SUS304 of 7 μm in thickness.

SUS foil B of embodiment: Metal foil using SUS304 of 50 μm in thickness.

Titanium foil A of embodiment: Titanium foil of 7 μm in thickness.

Titanium foil B of embodiment: Titanium foil of 50 μm in thickness.

Results of experiment are shown in Table 3. TABLE 3 Penetrating Heatquantity Total leak heat quantity transferring heat quantity Composition(W) end face (W) (W) Prior art 1 18.3 67.5 85.8 Prior art 2 18.3 0.518.8 SUS foil A 18.3 4.3 22.6 SUS foil B 18.3 30.5 48.8 Titanium foil A18.3 5.7 24.0 Titanium foil B 18.3 40.7 59.0

As clear from Table 3, the penetrating heat quantity is same in allvacuum heat insulators. However, a significant difference is noted inthe heat quantity transferring the end face of the vacuum heatinsulator. That is, the vacuum heat insulator using stainless steel foilor titanium foil of 50 μm in thickness as the gas barrier layer 305 canbe decreased in the total heat quantity leaking from the vacuum heatinsulator as compared with the vacuum heat insulator using aluminum foilof 7 μm in thickness. The vacuum heat insulator using stainless steelfoil or titanium foil smaller in thickness than 50 μm can be furtherdecreased in the total heat quantity leaking from the vacuum heatinsulator. Thus, the vacuum heat insulators having SUS foil A, SUS foilB, titanium foil A, and titanium foil B have an excellent insulatingperformance.

Embodiment 3c

Results of heat resistant durability test of vacuum heat insulator ofthe embodiment are reported. Samples of vacuum heat insulator used inthe experiment are same as the vacuum heat insulators used in thepreceding experiment 3 b In these samples of vacuum heat insulator, theinternal pressure of the laminate bag is measured in advance. Then thevacuum heat insulator is put in a thermostatic oven at 100° C., andsamples are taken out from the thermostatic oven at every specific time,and the internal pressure in the laminate bag is measured. On the basisof the result of measurement, the internal pressure in the laminate bagin 7 years is predicted. Results of experiment are recorded in Table 4.TABLE 4 Changes of internal pressure Initial Composition value 3 days 12days 1825 days 3650 days Prior art 1 12 12 12 10   15 Prior art 2 12 9.625 — — SUS foil A 1.1 1.1 1.1 9.0 14 SUS foil B 1.2 1.2 1.2 6.0 10Titanium 1.2 1.2 1.2 9.0 15 foil A Titanium 1.3 1.3 1.3 6.0 11 foil B

Generally, products using vacuum heat insulators are guaranteed ofquality for a period of 7 to 10 years. In the samples of vacuum heatinsulators of the embodiment, as shown in Table 4, the internal pressurepredicted after use of 7 years is about 20 Torr or less. Therefore, theinsulating performance can be assured for at least 7 years, and theseare usable as insulators sufficiently for 7 years.

By contrast, the vacuum heat insulator having the aluminum depositionlayer shown in prior art 2 presents an internal pressure in the laminatebag of about 25 Torr in 12 days from start of test, and the change ofthe internal pressure is very large. That is, gas has invaded into thelaminate bag to raise the internal pressure. Therefore, the insulatingperformance of the vacuum heat insulator is lowered in long-term use athigh temperature. That is, in the vacuum heat insulator in prior art 2,the heat resistance is not assured for a long period. Considering theuse for 10 years, the vacuum heat insulator using the stainless steelfoil or titanium foil of about 7 μm in thickness as the gas barrierlayer 305 is preferred.

Embodiment 3d

In the next experiment, the heating efficiency of the induction heatingdevice using the vacuum heat insulator of the embodiment wasinvestigated. The apparatus as shown in FIG. 3B was used in thisexperiment. That is, between the induction heating device 308 and theobject of heating 309 which is the cooking container, the vacuum heatinsulator 310 of the embodiment is inserted. That is, supposing theheating efficiency to be 100 when the vacuum heat insulator 310 is notinserted, the heating efficiency is measured when the vacuum heatinsulator 310 is inserted.

The gas barrier layer 305 of the vacuum heat insulator used in theexperiment includes aluminum foil of 7 μm in thickness, aluminumdeposition layer of 0.05 μm in thickness, ferritic stainless steel foilSUS430 of 1 to 100 μm in thickness, austenitic stainless steel foil 304of 7 μm in thickness, and titanium foil of 7 μm thickness. Results ofmeasurement are summarized in Table 5. TABLE 5 Thickness Heating Type(μm) efficiency Situation Without insulator — 100 Aluminum foil 7.0 0Ignited Aluminum deposition 0.05 99.5 layer US430 foil 1.0 99.0 5.0 95.07.0 93.0 10 90.0 15 85.0 20 80.0 50 50.0 100 0 Ignited US304 foil 1.099.3 5.0 96.7 7.0 95.3 10 93.3 15 90.0 20 82.8 50 67.0 100 0 IgnitedTitanium foil 1.0 99.0 5.0 95.0 7.0 93.0 10 90.0 15 84.9 20 79.9 50 49.8100 0 Ignited

As clear from Table 5, the vacuum heat insulator using stainless steelfoil or titanium foil of 50 μm or less in thickness as the gas barrierlayer 305 is hardly lowered in the heating efficiency if used in theinduction heating device. In particular, the vacuum heat insulator usingstainless steel foil or titanium foil of 10 μm or less in thickness hasa heating efficiency of 90% or more, and has an extremely excellentinsulating performance when used in induction heating device.

On the other hand, the vacuum heat insulator using aluminum depositionlayer of 0.05 μm in thickness as the gas barrier layer 305 has a heatingefficiency of 99.5%, and there is no effect on the heating efficiency,but as shown in Table 4, it is inferior in the heat resistantdurability. Therefore, the vacuum heat insulator using aluminumdeposition layer of 0.05 μm in thickness as the gas barrier layer 305cannot be used in the induction heating device.

By contrast, the vacuum heat insulator using aluminum foil of 7 μm inthickness is ignited as the aluminum foil is heated by inductionheating. Therefore, the heating efficiency could not be measured.Similarly, the vacuum heat insulator using stainless steel foil of 100μm in thickness or titanium foil of 100 μm in thickness is ignited.Hence the heating efficiency could not be measured.

As explained herein, according to the constitution of the exemplaryembodiment, the vacuum heat insulator capable of maintaining theexcellent insulating performance for a long period is obtained.

Further, the vacuum heat insulator using metal passing high frequencymagnetic field as the gas barrier layer exhibits an extremely excellentinsulating performance as the heat insulator for induction heatingdevice for heating water or food by heating the cooking container byinduction heating with the high frequency magnetic field applied in thecooking container.

Exemplary Embodiment 4

A hot insulating device using the vacuum heat insulator of the exemplaryembodiment of the invention is explained. The hot insulating device ofthe exemplary embodiment comprises a container for holding water orfood, and a vacuum heat insulator disposed outside of the container. Thevacuum heat insulator has a laminate bag and an insulting core containedin the laminate bag. The inside of the laminate bag is evacuated tovacuum, and is sealed. The laminate bag is made of a laminate film, andthe laminate film has a seal layer, a gas barrier layer, and aprotective layer.

In this constitution, since the inside of the laminate bag is kept invacuum state, the vacuum heat insulator has a higher insulatingperformance than the conventional insulating material such as glass woolor urethane. Therefore, the hot insulating device of the embodiment hasan extremely excellent insulating capacity owing to the actin of thevacuum heat insulator. Since the vacuum heat insulator uses theinsulating core, the laminate bag for keeping vacuum is not required towithstand atmospheric pressure. That is, the insulating core has thefunction of reinforcing material to withstand the atmospheric pressure.As a result, the laminate film is very thin. Therefore, the hotinsulating device of the embodiment is very light in weight. Further,since the laminate film has the protective layer, the vacuum heatinsulator free from effects of external stress is obtained. As a result,a lightweight and rigid hot insulating device is obtained.

Preferably, the laminate bag of the vacuum heat insulator is made of amaterial passing magnetic field. In this constitution, the hotinsulating device capable of heating by induction by application of highfrequency magnetic field is obtained.

Preferably, the laminate film has an aluminum deposition layer as gasbarrier layer. In this constitution, the surface radiation rate of thevacuum heat insulator is smaller, and hence the radiation heat from theinsulator is smaller. As a result, the hot insulating device having afurther excellent insulating performance is obtained.

Preferably, the laminate film has a deposition layer of a compound asgas barrier layer. In this constitution, loss of transmission of highfrequency magnetic field is prevented. As a result, an inductionheating-hot insulating device having an excellent insulating performanceand excellent heating efficiency is obtained.

Preferably, the laminate film has a deposition layer evaporated to thesupport layer having glass transition point of 100° C. or higher as thegas barrier layer. In this constitution, even in the high temperatureatmosphere, the vacuum heat insulator having excellent durability andinsulating performance is obtained.

Preferably, the container is made of a material containingheat-sensitive metal. In this constitution, the temperature of thecontainer can be measured by the magnetic field generator. Hence, thehot insulating device capable of finishing heating automatically atspecified temperature is obtained.

Embodiments of the invention are described below while referring to theaccompanying drawings.

Embodiment 4a

The hot insulating device of the embodiment of the invention isexplained by referring to FIG. 4A, FIG. 4B and FIG. 4C. In FIG. 4A, acontainer 401 for holding water or food is made of a ferromagneticmaterial. The surrounding of the container 401 is covered with a vacuumheat insulator 402. A vacuum heat insulator 404 is placed inside of alid 403 of the hot insulating device. A magnetic field generator 405 hasa function of generating a magnetic field for induction heating.

The composition of the vacuum heat insulators 402, 404 used in theembodiment is explained in FIG. 4B. The laminate bag is made of laminatefilm 406. In a seal portion 407, a plurality of laminate films 406, orfolded laminate films 406 are adhered by mutual adhesion of heat fusionlayers. An insulating core 409 is put in an inner bag 408. The inner bag408 containing the insulating core 409 is put in the laminate bag.

The inside gas in the laminate bag of the vacuum heat insulators 402,404 is exhausted, and is kept vacuum. The insulating core 409 has a veryporous material. As the insulating core 409, for example, syntheticsilica is used. Such insulating core 409 does not hold gas inside thecore or in the gap, and the thermal conductivity of the core itself isvery small. The inner bag 408 has a function of preventing scattering ofcore 409 or the like, As the inner bag, nonwoven cloth or other materialhaving gas permeability is used.

A detailed structure of the laminate film 406 is shown in FIG. 4C. Thelaminate film 406 has a seal layer 410, a support layer 412, a gasbarrier layer 411, and a protective layer 413. The gas barrier layer 411is disposed on the surface of the support layer 412 by vapor depositionor the like. The protective layer 413 has a function of protecting theentire laminate film from external stress. The seal layer 410 andsupport layer 412 are mutually adhered with an adhesive 414. The gasbarrier layer 411 and protective layer 413 are mutually adhered with anadhesive 415.

As the heat fusion layer 410, a thermoplastic resin such as polyolefinor polyester may be used. In this embodiment, the seal layer 410 is aundrawn polypropylene. The gas barrier layer 411 is thin layer ofaluminum or the like, drawn metal, or deposition layer. In thisembodiment, aluminum deposition layer is used as the gas barrier layer411. When the gas barrier layer 411 is made of aluminum, high frequencymagnetic field penetrates as far as its thickness is about 2 μm orsmaller. This has been confirmed by experiment.

The thickness of the aluminum deposition layer is about 50 nm, and thehigh frequency magnetic field passes sufficiently through the aluminumlayer of this thickness. The surface heat radiation rate of the aluminumdeposition layer is 0.01, and the heat radiation rate is extremelysmall. Since the heat radiation rate of the laminate film positioned onthe surfaces of the vacuum heat insulators 402, 404 is extremely low,the radiation heat from the surfaces of the vacuum heat insulator 402,404 is extremely small. As a result, the hot insulating device having anexcellent insulating performance is obtained.

As the support layer 412, polyester, polyamide or polyimide may be used.In the embodiment, polyethylene naphthalate (PEN) is used as the supportlayer 412. When the gas barrier layer 411 is very thin, the life of thegas barrier layer 411 depends on the state of the support layer 412.When the resin having a glass transition point of 100° C. or lower isused as the support layer 412, if the hot insulating device exceeds 100°C., the laminate film for composing the vacuum heat insulators 402, 404contacting with the hot insulating device also exceeds 100° C. At thesame time, the support layer 412 also exceeds 100° C. Therefore, ifusing the resin having a glass transition point of 100° C. or lower asthe support layer 412, the temperature of the support layer 412 changes,exceeding the glass transition point.

The resin drastically changes its properties at the glass transitionpoint. In particular, large expansion or shrinkage occurs at the glasstransition point. If the dimension of the support layer 412 is changednotably, the gas barrier layer 411 contacting with the support layer ispulled and stressed corresponding to expansion or shrinkage of thesupport layer, and is cracked. That is, due to difference in coefficientof thermal expansion between the support layer 412 and gas barrier 411,crack or pin hole may be formed in the gas barrier layer 411. Throughthe crack, fresh air invades into the vacuum heat insulator, and theinternal pressure of the vacuum heat insulator increases, therebylowering the insulating performance of the vacuum heat insulator.Accordingly, when heating and insulating the content including water andliquid, if using the support layer 412 having a glass transition pointof 100° C. or lower, the durability of the vacuum heat insulator isimpaired due to the stress applied to the gas barrier layer 411. Sincethe glass transition point of the PEN is about 120° C., a vacuum heatinsulator having an extremely high durability performance is obtained.As the protective layer 413, polyolefin, polyester, polyamide,polyimide, polycarbonate, fluoroplastic, or their combined material maybe used. In this embodiment, the PEN is used as the protective layer413.

The action of this composition is explained. First, water or food is putin the ferromagnetic container 401, and the lid 403 is put on. Thecontainer 401 is put on a magnetic field generator 405 such as anelectromagnetic cooker, and a high frequency magnetic field is applied.The applied high frequency magnetic field penetrates through the vacuumheat insulator 402, and reaches the container 401. Since the container401 is ferromagnetic, the container 401 is heated by eddy current. Bythe container 401 heated to high temperature, the water or food in thecontainer 401 is heated. After specified heating, the operation of themagnetic field generator 405 is stopped. If kept in this state or movedand used, the heat in the container 401 is isolated by the vacuum heatinsulators 402, 402 surrounding the container 401, and hardly escapesoutside. As a result, the water or food in the container 401 is kept athigh temperature state for a long period.

Specific examples of experiment are given below. The following samplesof hot insulating device are used in the experiment.

4A: Hot insulating device having the constitution of the embodiment(ordinary device).

4B: Hot insulating device using glass wool instead of vacuum heatinsulator (glass wool device).

4C: Hot insulating device using vacuum double container of stainlesssteel instead of vacuum heat insulator (vacuum double container device).

4D: Hot insulating device using aluminum foil of 6 μm in thickness asgas barrier layer of laminate film (aluminum foil device).

4E: Hot insulating device using PET resin as support layer of gasbarrier layer of laminate film (PET device).

In each hot insulating device, first, the container 401 is filled withone liter of water at 20° C. Using electric power of 1 kW, a highfrequency magnetic field is generated. By the induction heat of the highfrequency magnetic field, when water boils, application of highfrequency magnetic field is stopped. Letting stand at room temperaturein this state, the temperature in the container 401 is measured in 6hours. This operation is repeated. Results of the experiment are givenin Table 6. The mass of each hot insulating device is also recorded inTable 6. TABLE 6 1st 100th Water Container Water Container Mass boilingtemperature boiling temperature (g) time (min) (° C.) time (min) (° C.)Ordinary 500 7.0 90 7.0 90 device Glass wool 550 7.2 75 7.2 75 deviceVacuum 1300 Not heated Unable Not heated Unable double to test to testcontainer device Aluminum 500 Not heated Unable Not heated Unable foildevice to test to test PET device 500 7.0 90 7.1 80

As clear from Table 6, the ordinary device has a light mass, and isexcellent in induction heating performance, insulating performance, anddurability.

Embodiment 4b

Other experiment of the exemplary embodiment is explained by referringto FIG. 4D and FIG. 4E. Same parts are in embodiment 4a are identifiedwith same reference numerals and their description is omitted.

FIG. 4D shows a pot type hot insulating device. The hot insulatingdevice as the upper limit water level 421 in ordinary state. The hotinsulating device has a tap 422, and this tap 422 is a port for pouringthe water or liquid in the container 401 to outside.

A sectional view of the laminate film used in the embodiment is shown inFIG. 4E. The laminate film has a heat fusion layer 423, gas barrierlayers 424, 425, a protective layer 427, and adhesive layers 428, 429.The gas barrier layer 424 is adhered to the surface of the support layer426 by vapor deposition or the like. The gas barrier layer 425 isadhered to the protective layer 427 by vapor deposition or the like,using the protective layer 427 as the base material. The adhesive layer428 adheres the heat fusion layer 423 and support layer 426, and theadhesive layer 429 adheres the gas barrier layer 424 and gas barrierlayer 425.

As the gas barrier layers 424, 425, metal deposition layer, ordeposition layer of compound of alumina or silica may be used. In thisembodiment, a deposition layer of silica as compound is used.

When a compound is used in the gas barrier layers 424, 425, since thehigh frequency magnetic field penetrates through the gas barrier layersof this compound, loss of high frequency magnetic field energy isprevented. Hence, an ideal induction heating is possible. In thisembodiment, two gas barrier layers 424, 425 are provided on both sidesof the adhesive layer, but not limited to this composition, the gasbarrier layer may be disposed in a single layer, or two or more layers.As the first gas barrier layer 424 and the second gas barrier layer 425are close to each other, if a pin holes are formed in the gas barrierlayer, the pin holes are plugged with each other, and invasion of freshair into the vacuum heat insulator is prevented. As a result, the vacuumheat insulator and hot insulating device of a very high reliability areobtained. In this embodiment, the material of the container 401 is aheat-sensitive metal changing from ferromagnetic property to weakmagnetic property.

The operation of the embodiment is explained. First, water or liquid ispoured into the container 401 up to the line 421. The container 401 isput on the magnetic field generator 405, and high frequency magneticfield is generated. By the high frequency magnetic field, the container401 is heated, and the water or liquid in the container 401 is heated.At the water boiling temperature, the heat-sensitive metal changes toweak magnetic property. The change of magnetic property of theheat-sensitive metal is detected by the magnetic field generator 405,and the magnetic field generator 405 automatically stops generation ofmagnetic field. As a result, water heating is finished automatically.The container holding the boiling water may be kept in the same place ormay be moved. By inclining the container 401, the water is poured outfrom the tap 422. As the tapping method, besides, the air pump system,power pump system or the like may be employed.

Specific examples of experiment are given below. The following samplesof hot insulating device are used in the experiment.

4F: Hot insulating device having the constitution of the embodiment(ordinary device).

4G: Hot insulating device using glass wool instead of vacuum heatinsulator (glass wool device).

4H: Hot insulating device using vacuum double container of stainlesssteel instead of vacuum heat insulator (vacuum double container device).

4I: Hot insulating device using aluminum foil of 6 μm in thickness asgas barrier layers 424, 425 of laminate film (aluminum foil device).

4J: Hot insulating device using aluminum deposition layer of 50 nm inthickness as gas barrier layers 424, 425 of laminate film (aluminumdeposition device).

4K: Hot insulating device using PET resin as support layer of gasbarrier layers 424, 425 of laminate film (PET device).

In each hot insulating device, first, the container 401 is filled withone liter of water at 20° C. Using electric power of 1 kW, a highfrequency magnetic field is generated. By the induction heat of the highfrequency magnetic field, when water boils, application of highfrequency magnetic field is stopped. Letting stand at room temperaturein this state, the temperature in the container 401 is measured in 6hours. This operation is repeated. Results of the experiment are givenin Table 7. The mass of each hot insulating device is also recorded inTable 7. TABLE 7 1st 100th Container Container Water temper- Watertemper- Mass boiling ature boiling ature (g) time (min) (° C.) time(min) (° C.) Ordinary device 500 6.8 89 6.8 89 Glass wool device 550 7.275 7.2 75 Vacuum double 1300 Not heated Unable Not heated Unablecontainer device to test to test Aluminum foil 500 Not heated Unable Notheated Unable device to test to test Aluminum 500 7.0 90 7.0 90deposition device PET device 500 7.0 90 7.1 80

As clear from the table, the ordinary device has a light mass and can beheated by induction, and is excellent in insulating performance, anddurability. By comparison of hot insulating devices using aluminumdeposition layer and silica deposition layer as the gas barrier layers424, 425, as light loss of magnetic field is found in the hot insulatingdevice having aluminum deposition layer. Accordingly, the hot insulatingdevice having silica deposition layer has a superior heating efficiencyas compared with the hot insulating device having aluminum depositionlayer. However, since the aluminum deposition layer is smaller in theheat radiation rate, the radiation heat is smaller. Therefore, the hotinsulating device having aluminum deposition layer is higher ininsulating performance than the hot insulating device having silicadeposition layer. Therefore, whether either the aluminum depositionlayer or silica deposition layer should be used, or both should be usedmay be properly selected depending on the method of use of the hotinsulating device.

As clear from the description herein, by the constitution of theembodiment, a hot insulating device having an extremely high insulatingperformance may be obtained. Further, a hot insulating device of lighterweight is obtained. Still more, a hot insulating device having anexcellent durability is obtained.

In addition, since the vacuum heat insulator passes high frequencymagnetic field, the hot insulating device capable of heating fromoutside by induction heating is realized.

By forming the container of a material containing heat-sensitive metal,the hot insulating device capable of controlling the temperature orheating automatically is realized.

Exemplary Embodiment 5

An electric water heater using a vacuum heat insulator of an exemplaryembodiment of the invention is explained. The electric water heater ofthe exemplary embodiment comprises a water storage container, a heaterfor heating the water in the container, a tapping route for dischargingthe water, and a vacuum heat insulator disposed around the water storagecontainer. The vacuum heat insulator has a laminate bag, and aninsulating core placed in the laminate bag, and the inside of thelaminate bag is evacuated to vacuum. The laminate bag is made of alaminate film, and the laminate film has the gas barrier layer, aprotective layer, and a seal layer.

The gas barrier layer has a resin film base material, and a depositionlayer evaporated to the base material. The protective layer is disposedon the surface of the deposition side of the deposition layer, and ismade of the same material as the resin film base material. The seallayer is positioned at the inside of the laminate bag. As the seallayers are mutually adhered, the laminate bag is sealed.

In this constitution, without breakage of gas barrier layer, theinternal vacuum state of the laminate bag is held. Hence, the excellentinsulating performance of the vacuum heat insulator is maintained for along time without decline. As the deposition layer is used for the gasbarrier layer, the heat flowing into the low temperature part from thehigh temperature part through the gas barrier layer itself is kept tominimum. Therefore, the insulating performance of the entire vacuum heatinsulator is enhanced. As a result, the hot insulating electric power ofthe electric water heater can be curtailed. The vacuum heat insulator inthis exemplary embodiment has a thermal conductivity of about 0.006kcal/m·h° C. (0.007 W/m·K) at 25° C.

The electric water heater having the vacuum heat insulator having thegas barrier layer to which the deposition layer is evaporated is smallin the heat quantity leaking from the end through the gas barrier layeritself, and hence the hot insulating electric power is kept smaller ascompared with the electric water heater having the vacuum heat insulatorusing metal foil gas barrier layer.

Moreover, since the protective layer and base material are made of samematerial, thermal expansion or thermal shrinkage caused by temperaturechanges of the protective layer and base material is always the same. Ithence prevents generation of uneven stress of deposition layer due tothermal expansion or thermal shrinkage, and breakage of deposition layeris avoided. As a result, the durability of the vacuum heat insulator isenhanced, and the thermal durability of the electric water heater isimproved. By contrast, if the protective layer and base material aremade of different materials, the coefficient of thermal shrinkage isdifferent between the base material of the gas barrier layer and theprotective layer of the deposition side, and an uneven stress isgenerated in the deposition layer. As a result, the deposition layer maybe cracked, and the insulating performance of the vacuum heat insulatordrops.

Preferably, the gas barrier layer has a plurality of gas barrier layers,and at least two deposition layers are laminated so that each depositionside may face each other. If the deposition layers have small holescalled pin holes, by adhering the deposition sides together, thepositions of the pin holes are mutually covered, and invasion of freshair into the vacuum heat insulator is prevented. As a result, the gasbarrier performance is improved substantially. In this constitution, theinternal vacuum of the laminate bag is maintained for a long period, andthe durability of the insulating performance of the vacuum heatinsulator is extremely enhanced. Hence, the thermal durability of theelectric water heater is further enhanced.

Preferably, the laminate film further has a metal foil. The metal foilfunctions as gas barrier layer. That is, the laminate film has the gasbarrier layer of the deposition layer and metal foil. In thisconstitution, the thermal durability of the vacuum heat insulator isenhanced, and hence the thermal durability of the electric water heateris further improved.

Preferably, the laminate film further has a metal foil, and the metalfoil is cut off at a position of the end of the opposite side of thewater storage container of the vacuum heat insulator. The metal foil isdisposed at a position excluding the end of the laminate bag. As the gasbarrier layer has a deposition layer, the heat flowing into the lowtemperature side from the high temperature part through the gas barrierlayer itself can be suppressed, and moreover since the metal foil isdisposed at a position excluding the end of the laminate bag, heatconduction from the high temperature side to the low temperature sidethrough the metal foil is prevented. Accordingly, the heat resistingtemperature of the vacuum heat insulator is further enhanced, and thehot insulating electric power of the electric water heater is suppressedmuch lower.

Preferably, the laminate film further has a metal foil, and the sealportion by mutual heat fusion of seal layers of the laminate film isfolded to the opposite side of the container. By folding the sealportion including the metal foil to outside, leak of heat from the sealportion through the metal foil itself is prevented. As a result, the hotinsulating electric power of the electric water heater is saved. Thethermal durability of the electric water heater is further enhanced.

Preferably, the resin film base material has polyethylene naphthalate.Since polyethylene naphthalate has a high heat resisting temperature, ifthe vacuum heat insulator is used in high temperature atmosphere,breakage of the deposition layer is prevented. As a result, the thermaldurability of the vacuum heat insulator is enhanced and the thermaldurability of the electric water heater is enhanced.

Embodiments of the invention are described below while referring to thedrawings.

Embodiment 5a

The electric water heater of the embodiment is described while referringto FIG. 5A to FIG. 5F. In FIG. 5A, an electric water heater main body501 (main body hereinafter) comprises a water storage container 502(container hereinafter), a middle stopper 503, an upper lid 504, a waterleak preventive valve 506, a steam passage 505, a motor 507, a pump 508,a suction port 509, a discharge port 510, a tapping pipe 511, a tap 512,a heater 513, a temperature detector 514, a start switch 515, a pushbutton 516, a rod 517, a compression spring 518, a controller 519, and avacuum heat insulator 520.

The container 502 is disposed inside of the main body, and has afunction of storing water. The container 502 has a cylindrical shapemeasuring 184 mm in inside diameter and 200 mm in depth. The middlestopper 503 is disposed to seal the opening of the container 502. Theupper lid 504 closes the upper part of the main body 501. The steampassage 505 is disposed in the upper lid, and one end of the steampassage 505 communicates with the inside of the container 502 throughthe middle stopper 503, while the other end communicates with theatmosphere. The water leak preventive valve 506 is disposed in the steampassage 505, and has a function of cutting off the steam passage 505 incase of tumbling or collapse. The steam passage 505 is bent in acomplicated form. Accordingly, when the water in the container 502boils, in the case the inside pressure of the container 502 is higherthan the atmospheric pressure, the steam is discharged outside of themain body 501 through the steam passage 505, and hence the fresh air isnot mixed easily with the air between the water level in the container502 and the upper lid 504 (called internal air hereinafter). The motor507 is disposed in the bottom between the main body 501 and thecontainer 502. The pump 508 is driven by the motor 507. The suction port509 of the pump 508 communicates with the bottom of the container 502.The discharge port 510 of the pump 508 communicates with the tappingpipe 511. The hot water is poured out of the electric water heaterthrough the tap 512. Therefore, in the tapping route, the hot water runsthrough the container 502, suction port 509, pump 508, discharge port510 of pump 508, and tapping pipe 511, and flows out from the tap 512.The heater 513 has a doughnut shape with a hollow center, and isdisposed in the lower part of the container 502. The start switch 515for driving the motor 507 has a variable resistor, and is actuatedthrough the rod 517 by the pushing operation of the pushbutton 516. Thespring 518 is thrusting the rod 517 always in the upward pushingdirection. The controller 519 receives a signal from the temperaturedetector 514, and controls the heater 513 and others. The vacuum heatinsulator 520 is disposed as being wound to the side of the container502. The vacuum heat insulator 520 prevents the heat of the container502 from escaping from the side of the main body 501.

The vacuum heat insulator 520 is explained in detail. FIG. 5B is asectional view of the vacuum heat insulator 520. The vacuum heatinsulator 520 has a laminate bag, an inner bag 523, and an insulatingcore 522. The core 522 is put in the inner bag 523. The inner bag 523 isdisposed in the laminate bag. The inner bag 523 is formed by adheringthe laminate films 524, 531. The inside of the laminate bag is evacuatedto vacuum, and the vacuum heat insulator 520 has a flat rectangularshape as shown in FIG. 5C. The existing portion of the core 522 is theinsulating portion 538. In the heat seal portion 537, the seal layers525, 536 are fused and sealed.

As shown in FIG. 5D, the vacuum heat insulator 520 is wound around thewater storage container 502. The inside of the vacuum heat insulator 520directly contacts with the container. Therefore, the inner side of thevacuum heat insulator 520 requires the material having higher thermaldurability and better gas barrier performance than the opposite side.

The laminate film 524 includes a seal layer 525, a base material 526, agas barrier layer 527, a protective layer 528, and a gas barrier layer529. The laminate film 531 includes a protective layer 532, a gasbarrier layer 535, and a seal layer 536. The core 522 is made of amaterial having a small thermal conductivity. Holes and gaps formed inthe core 522 communicate with the outside of the core. The core 522 ismade of organic or inorganic material. When the vacuum heat insulator isused in high temperature condition as in the electric water heater, amaterial not generating heat at high temperature is used. Usablematerials for the core include pearlite, sandy balloon, syntheticsilica, etc. In the embodiment, synthetic silica powder is used as thecore 522. The synthetic silica powder has very fine particles, and thethermal conductivity of particles is very small. Further, the core usingthe synthetic silica powder shows a very small thermal conductivity,regardless of the pressure, at pressure of 20 Torr or less. Accordingly,the vacuum heat insulator using synthetic silica exhibits an extremelyexcellent insulating performance when used at high temperature.

The seal layers 525, 536 have the role of keeping vacuum inside theadhered laminate films 524, 531. As the seal layers, materials to beheated and sealed easily are preferred. Since the electric water heateris heated to temperature of about 100° C., the seal layer is preferredto be made of a material not deteriorating at 100° C. In thisembodiment, the seal layers 525, 536 are made of undrawn polypropylene.This polypropylene is a polymer having a high heat resistance, andhaving a properly enhanced in crystallinity.

The gas barrier 527 of the first laminate film 524 has an aluminum foil529 and an aluminum deposition layer 530. The aluminum foil 529 hasenough width to cover the core 522. The second gas barrier layer 535 ofthe second laminate film 531 is made of an aluminum foil. These gasbarrier layers 527, 535 have the role of cutting off the gas passingthrough the laminate films 524, 531. If the laminate films 524, 531 donot have large gas shielding property, the internal pressure of thevacuum heat insulator 520 rises. When the internal pressure of thevacuum heat insulator 520 exceeds 20 Torr, the thermal conductivity ofthe vacuum heat insulator 520 also climbs up, and when the internalpressure further elevates, its thermal conductivity becomes extremelylarger than the insulating performance of the initial vacuum heatinsulator. Therefore, as the laminate film, the performance capable ofcutting off the gas for a long period at temperature of about 100° C. isrequired. The greater the thickness of the shielding material forcutting off the gas penetration, the higher is the long-termreliability. However, a metal is used as the gas barrier layer of thevacuum heat insulator, and the thickness of the metal becomes smaller,the heat quantity propagating through the metal itself is smaller, andthe heat insulation is improved.

In the embodiment, therefore, as the gas barrier layer 527, bothaluminum foil 529 of 5 to 6 μm, and aluminum deposition layer 530 of 30to 100 nm in thickness are used. As the gas barrier layer 535, aluminumfoil of 5 to 6 μm, or aluminum deposition layer of 30 to 100 nm is used.The thickness of the deposition layer 530 is preferred to be in a rangeoff 30 to 100 nm, but not limited to this thickness, it may be used inany desired thickness.

In the laminate film 524, the protective layer 528 has a role ofprotecting the seal layer 525 and gas barrier layer 529. In the laminatefilm 531, the protective layer 532 has a role of protecting the gasbarrier layer 535 and seal layer 536. It is most preferred that the basematerial 526 and protective layer 528 are same in the coefficient ofthermal shrinkage, but not limited to this, any desired materials may beused. If the coefficient of thermal shrinkage is different between theprotective layer and base material disposed at both sides of thedeposition layer, an uneven stress acts son the deposition layer, andthe deposition layer may be broken. Such breakage of the depositionlayer is prevented when the base material and protective layer are madeof same material, and the heat resistance and long-term reliability ofthe vacuum heat insulator are enhanced.

In the embodiment, the base material 526 and protective layer 528 aremade of polyethylene naphthalate (PEN). At 100° C. corresponding to themaximum temperature in the electric water heater, the coefficient ofthermal shrinkage of PEN is about 0.4% or lower, and the coefficient ofthermal shrinkage of PEN is very small as compared with that of PET. Atthis level of thermal shrinkage, the deposition layer is not broken. Inthe laminate film 531, at a position directly contacting with the gasbarrier layer, the polyester layer 533 is disposed. As the polyesterlayer 533, PET is used.

Although PET is slightly inferior to PEN in heat resistance, thelaminate film 531 side does not directly contact with the water storagecontainer 502, and the maximum temperature is about 40° C. Hence, thelaminate film 531 using PET as the protective layer sufficientlysatisfies the heat resistance. Further, a nylon layer 534 is disposed inthe outermost layer of the protective layer 532. During use of electricwater heater, when mounting or dismounting the electric water heater,the electric water heater often contacts with other parts and is likelyto be damaged. However, the nylon has a high slipping performance and israrely injured. By disposing the slipping nylon in the outermost layer,the vacuum heat insulator can be installed smoothly and the assemblingperformance is enhanced.

When winding the vacuum heat insulator around the container 502, theheat seal may be broken. At this time, as shown in FIG. 5D, the vacuumheat insulator is wound around the container 502 so that the sealportion may be positioned at the outside of the cylindrical form. Thus,the end portion of the container 502 is the aluminum deposition layeronly, and the heat propagating through the aluminum itself can besuppressed. As a result, the insulating performance of the entire vacuumheat insulator is enhanced.

The action of the embodiment is explained. Water is poured into thecontainer 502, and the power is turned on. The water temperature in thecontainer 502 is measured by the temperature detector 514, and itssignal is sent into the controller 519, and the controller starts tosupply power into the heater 513 by receiving this signal. When thewater in the container 502 boils, power feed to the heater 513 isstopped. Then, receiving a signal from the temperature detector 514, thecontroller 519 controls the heater 513 so that the temperature of thecontainer 502 maybe kept nearly at a constant temperature. When tapping,the pushbutton 516 is pressed. The motor 507 operates and the water inthe container 502 is discharged outside of the electric water heaterfrom the tap 512 through the tapping pipe 511 by means of the pump 508.

Embodiment 5b

Examples of experiment of heat insulation and thermal durability ofvarious vacuum heat insulators are shown below. The following samples ofvacuum heat insulators are prepared.

5A: Vacuum heat insulator having aluminum foil with gas barrier layerdisposed at both sides (both-side foil).

5B: Vacuum heat insulator having aluminum deposition layer with gasbarrier layer disposed at both sides, using PET in deposition basematerial and PEN protective layer (both-side deposition PET).

5C: Vacuum heat insulator having aluminum deposition layer with gasbarrier layer disposed at both sides, using PEN in base material and PENprotective layer (both-side deposition PEN).

Using these vacuum heat insulators, as shown in FIG. 5D, the vacuum heatinsulator is wound around the container 502 in a cylindrical form. Thevacuum heat insulator is wound around the container 502 so that the sealportion may come to the outside of the cylindrical vacuum heatinsulator. In this way, the electric water heaters having these vacuumheat insulators are fabricated. Pouring water into the container of eachelectric water heater, the hot insulating electric power is measured.The water is kept at 96.5° C., and the ambient temperature is 20° C. Thetemperature is measured in well balanced state. Results of experimentare summarized in Table 8. TABLE 8 Power difference Insulating powerfrom both-side foil Composition (Wh/h) (Wh/h) Both-side foil 31.8 0Both-side deposition 28.7 −3.1 PET Both-side deposition 28.7 −3.1 PEN

The vacuum heat insulator using aluminum deposition layer as the gasbarrier layer of vacuum heat insulator is lower in the electric powerrequired for hot insulation than the vacuum heat insulator usingaluminum foil. That is, by using aluminum deposition layer as gasbarrier layer, the heat quantity propagating through the gas barrierlayer itself can be suppressed, and the insulating performance of thevacuum heat insulator is enhanced. Therefore, by using such vacuum heatinsulator, an electric water heater small in electric power for hotinsulation is realized.

Embodiment 5c

A thermostatic oven at 100° C. is prepared. The following vacuum heatinsulators are used

5A: Vacuum heat insulator having same both-side foil as in experiment 5a.

5B: Vacuum heat insulator having same both-side deposition PET as inexperiment 5 a.

5C: Vacuum heat insulator having same both-side deposition PEN as inexperiment 5 a.

In these samples, the internal pressure of the vacuum heat insulator ismeasured preliminarily, and all vacuum heat insulators are put in thethermostatic oven at 100° C., and the heat resistance is tested. Thevacuum heat insulators using both-side deposition PET are taken out ofthe thermostatic oven in 3 days and 12 days, and the internal pressureis measured. The vacuum heat insulators using both-side foil are takenout of the thermostatic oven in 3 days, 12 days, 1825 days, and 3650days, and the internal pressure is measured. The vacuum heat insulatorsusing both-side deposition PEN are taken out of the thermostatic oven in3 days, 224 days, and 336 days, and the internal pressure is measured.Herein, the temperature of 100° C. is the maximum temperature exposed tothe vacuum heat insulator used in the electric water heater, that is,the temperature of the part contacting with the container 502 when thecylindrical vacuum heat insulator is wound around the container 502.Results of heat resistance test of these vacuum heat insulators aresummarized in Table 9. TABLE 9 Internal pressure (Torr) Com- 3 12 224336 1825 3650 position Before days days . . . days days . . . days daysBoth-side 1.2 1.2 1.2 . . . . . . 20 or 20 or foil less less Both-side1.2 9.6 20 or deposition more PET Both-side 1.2 1.5 16 20 or depositionmore PEN

In Table 9, at temperature of about 100° C., the vacuum heat insulatorscomprising the gas barrier layer having aluminum deposition layer, thebase material having PEN, and the protective layer having PEN exhibitthe best long-term heat resistance and reliability. That is, the vacuumheat insulator having the base material and protective material made ofsame material exhibits an extremely excellent long-term reliability. Asa result, the electric water heater not lowered in the insulatingperformance for a long period and small in hot insulation powerconsumption is realized. However, the vacuum heat insulator comprisingthe deposition base material having PET and the protective layer havingPEN is slightly inferior in heat resistance.

Embodiment 5d

A thermostatic oven at 100° C. is prepared. The following vacuum heatinsulators are used

5A: Vacuum heat insulator having same both-side foil as in experiment 5a.

5C: Vacuum heat insulator having same both-side deposition PEN as inexperiment 5 a.

5D: Vacuum heat insulator using aluminum foil as gas barrier layer ofone laminate film, and aluminum deposition layer using PEN as basematerial as shown in FIG. 5E as gas barrier layer of other laminatefilm, and placing aluminum foil 539 in the portion 537 contacting withthe core (one-side foil).

The vacuum heat insulator having both-side foil, and vacuum heatinsulator having both-side deposition PEN are wound around the container502 cylindrically so that the heat seal portion may be positioned at theoutside as shown in FIG. 5D. This state is respectively defined asboth-side foil outer fold and both-side deposition outer fold. One ofthe vacuum heat insulators having one-side foil of sample 5D is woundaround the container 502 so that the heat seal portion may be positionedoutside of the cylindrical form as shown in FIG. 5D so that only thealuminum foil side of the gas barrier layer may be positioned to theinside of the cylindrical form. This state is defined the one-side foilouter fold. Other vacuum heat insulators are wound around the container502 so that the seal portion may be positioned at the inside of thecylindrical form as shown in FIG. 5F, so that only the aluminum foilside of the gas barrier layer may be at the inside of the cylindricalform. This state is defined the one-side foil inner fold.

Electric water heaters having these vacuum heat insulators are prepared.Pouring water into these electric water heaters, the electric powerrequired for hot insulation of these electric water heaters is measured.The water is kept at temperature of 96.5° C., and the ambienttemperature is 20° C. The temperature is measured after balancedsufficiently. Results of experiment are shown in Table 10. TABLE 10Insulating power Insulating based on both-side power foil outer foldComposition (Wh/h) (Wh/h) Both-side foil outer fold 31.8 0 One-side foilinner fold 31.0 −0.8 One-side foil outer fold 30.0 −1.8 Both-sidedeposition outer 28.7 −3.1 fold

Table 10 teaches the following. In the vacuum heat insulator of one-sidefoil outer fold, the gas barrier layer having aluminum deposition layercan suppress the heat flowing in through the aluminum itself, and hencethe insulating performance of the entire vacuum heat insulator can beenhanced. Therefore, by using such vacuum heat insulator, the electricwater heater of small power consumption required for hot insulation isrealized.

Embodiment 5e

A thermostatic oven at 100° C. is prepared. The following vacuum heatinsulators are used

5A: Vacuum heat insulator having same both-side foil as in experiment 5c.

5C: Vacuum heat insulator having same both-side deposition PEN as inexperiment 5 c.

5D: Vacuum heat insulator having same one-side foil as in experiment 5C.

In these vacuum heat insulators, the internal pressure is measuredpreliminarily, and all vacuum heat insulators are put in thethermostatic oven at 100° C. The heat resistance is tested. The vacuumheat insulators having both-side foil and vacuum heat insulators havingone-side foil are taken out of the thermostatic oven in 1825 days and3650 days, and the internal pressure is measured. The vacuum heatinsulators having both-side deposition PEN are taken out of thethermostatic oven in 224 days, and 336 days, and the internal pressureis measured. Results of heat resistance test of these vacuum heatinsulators are summarized in Table 11. TABLE 11 Internal pressure (Torr)224 336 1825 3650 Composition Before . . . days days . . . days daysBoth-side foil 1.2 . . . . . . 20 or 20 or less less Both-side 1.2 16 20or deposition PET more One-side foil 1.2 20 or 20 or less more

As clear from Table 10 and Table 11, at temperature of 100° C., in thevacuum heat insulators of one-side foil outer fold, the vacuum heatinsulator having aluminum deposition layer is enhanced in the insulatingperformance of the entire vacuum heat

1-6. (canceled)
 7. A vacuum heat insulator comprising: a laminate bag,and an insulating core placed in said laminate bag, wherein an inside ofsaid laminate bag is evacuated to vacuum, said laminate bag is made of alaminate film, said laminate film includes a first support layer, afirst deposition layer evaporated on said first support layer, a secondsupport layer, and a second deposition layer evaporated on said secondsupport layer, each one of said first deposition layer and seconddeposition layer has at lest one of metal and metal oxide, and each oneof said first support layer and second support layer has a plastic filmhaving a glass transition point of 87° C. or higher,
 8. The vacuum heatinsulator of claim 7, wherein the surface of the first deposition layerand the surface of the second deposition layer are mutually adhered toeach other. 9-18. (canceled)
 19. A vacuum heat insulator comprising: alaminate bag, and an insulating core placed in said laminate bag,wherein an inside of said laminate bag is evacuated to vacuum, saidlaminate bag is made of a laminate film, said laminate film includes abase material layer, a deposition layer evaporated on said base materiallayer, a metal foil, and a seal layer, said laminate bag as a sealportion positioned at the end of said laminate film, said seal portionis formed by bonding of said seal layer, and said metal foil ispositioned at a position excluding at least a part of said seal portion.20. The vacuum heat insulator of claim 19, wherein said deposition layerhas an aluminum deposition layer, and said metal foil has an aluminumfoil.
 21. (canceled)
 22. The vacuum heat insulator of claim 19, whereinsaid base material layer has a first base material layer and a secondbase material layer, said deposition layer has a first deposition layerand a second deposition layer, and said first deposition layer andsecond deposition layer are adhered face to face. 23-25. (canceled) 26.The vacuum heat insulator of claim 22, wherein said metal foil islaminated between said first deposition layer and second depositionlayer.
 27. The vacuum heat insulator of claim 19, wherein said basematerial layer and deposition layer are laminated between said metalfoil and seal layer. 28-64. (canceled)